IN VITRO PRODUCTION OF COLONY-STIMULATING ACTIVITY. I. EXPOSURE OF MOUSE PERITONEAL CELLS TO ENDOTOXIN

Cell suspensions, obtained from bone marrow, spleen, thymus, lung, liver, and from peritoneal washings, were incubated in vitro with low concentrations of endo-toxin and the supernatant media assayed for colony-stimulating activity (CSA). Peritoneal cells were markedly responsive. The kinetics of CSA production in vitro by peritoneal cells were not remarkably different from that seen in vivo following intravenous administration of endotoxin. The activities of CSA prepared from peritoneal cells and serum were compared following serial dilution; both gave a similar linear relationship when plotted as a function of log-concentration. The bulk of the CSA was produced by adherent peritoneal cells. Separation of peritoneal cells by velocity sedimentation showed that the CSA-producing cell had a sedimentation velocity of 7 mm/hr. Cells with this sedimentation velocity were found to be large mononuclear cells which demonstrated adherence and phagocytosis.     

In vitro differentiation of B lymphocytes from pre-B cells.

Adult bone marrow contains both B lymphocytes and their immediate precursors, pre-B cells. These two cells differ in size and can be separated by velocity sedimentation; B cells are enriched in the subpopulation of cells sedimenting at between 2.0 and 3.5 mm/hr and pre-B cells in the subpopulation between 5.0 and 7.0 mm/hr. Incubation of pre-B cells in vitro for 4 or 5 days leads to their differentiation into functional B lymphocytes. The transition form pre-B to B appears to occur in two steps. The first step gives mitogen responsive B cells with an intermediate sedimentation velocity and the second step produces typical small, slowly sedimenting B cells. Pre-B cells can be quantified by using a limiting dilution assay and occur at a frequency of 1/60 in the subpopulation of rapidly sedimenting bone marrow cells.     

Leukemia in AKR mice: III. Size distribution of suppressor T-cells in AKR leukemia and neonatal mice

Suppression of in vitro antibody forming potential of normal cells by leukemic cells of AKR and normal neonatal mice have many similarities. In both cases the suppression is by cell contact rather than by the elaboration of soluble suppressive factors and the suppression is sensitive to both x-irradiation and mitomycin C treatment. When the size distribution of suppressing cells in thymus and spleen were compared by velocity sedimentation, both leukemic and neonatal suppressing cells had similar size distribution in each organ. Both large and small cells in the thymus suppress but only large cells (sedimentation velocity >3.5 mm/hr) in the spleen are able to suppress. Leukemic cells in lymph node have a splenic size distribution, viz., only large cells suppress. Both large and small cells of a subcutaneously growing long passage AKR lymphoma are able to suppress. While large cells contain the bulk of cells actively incorporating tritiated thymidine and thus probably in cycle, small but significant amounts of incorporation in small suppressing cells is also seen.     

Two functionally distinct anti-tumor effector cells isolated from primary murine sarcoma virus-induced tumors.

The ability of cells from primary MSV-induced tumors to function as effector cells in vitro was evaluated. Host cells were isolated by enzymatic disaggregation of the tumor and fractionated by sedimentation velocity at unit gravity on a Ficoll gradient. Characterization of these cells indicated that 30 to 40 % were T lymphocytes, about 50% were macrophages and less than 5% were B lymphocytes. Two different functional activities were mediated by these cells: cytolysis, as measured by the CRA, and inhibition of proliferation, as measured by the GIA. The effector cells in the CRA were T cells with sedimentation velocities of 3.5 to 4.0 mm/hr, whereas those cells which mediated the GIA were presumably macrophages and displayed a heterogeneity in size two peak sedimentation velocities, one at 4.0 mm/hr and another at 6.0 mm/hr. Activity by the effector cells in the CRA was antigen specific in contrast to the activity in the GIA which was directed against cells which did not carry detectable cross-reacting antigens.     

Separation of cells by velocity sedimentation

A system for fractionating populations of living cells by velocity sedimentation in the earth's gravitational field is described. The cells start in a thin band near the top of a shallow gradient of 3% to 30% fetal calf serum in phosphate buffered saline at 4°C. Cell separation takes place primarily on the basis of size and is approximately independent of cell shape. A sharply-defined upper limit, called the streaming limit, exists for the cell concentration in the starting band beyond which useful cell separations cannot be achieved. This limit, which varies with the type of cell being sedimented, can be significantly increased by proper choice of gradient shape. For sheep erythrocytes (sedimentation velocity of 1.6 mm/hour) it is 1.5 × 10⁷ cells/ml. Measured and calculated sedimentation velocities for sheep erythrocytes are shown to be in agreement. The technique is applied to a suspension of mouse spleen cells and it is shown, using an electronic cell counter and pulse height analyzer, that cells are fractionated according to size across the gradient such that the sedimentation velocity (in mm/hour) approximately equals r²/4 where r is the cell radius in microns. Since cells of differing function also often differ in size, the system appears to have useful biological applications.     

Characterization of rat bone marrow lymphoid cells. I. A study of the distribution parameters of sedimentation velocity, volume and electrophoretic mobility

Various cell populations in rat bone marrow were characterized by means of a two dimensional separation using velocity sedimentation and free flow electrophoresis and by electrical sizing of the separated cells. Up to 4.5 mm/hr five different populations with discrete distributions in volume (coefficient of variation 10% to 13%) and sedimentation velocity (coefficient of variation 6% to 10%) were observed. Three of the small sized populations represented lymphocytes and small normoblasts and two of the larger sized populations represented myeloid cells. Almost all of these cells were in the G0/G1 cycle phase. In the faster sedimenting fractions which contained immature myeloid, erythroid and undefined blast cells and two S phase populations, discrete volume distributions were not evaluated. The cell populations with homogeneous volume (particularly the small lymphocytes) showed high density variations which condiserably impair the separation resolution. The cells sedimenting slower than 3.5 mm/hr were further separated by means of free flow electrophoresis into three peaks differing in electrophoretic mobility (EPM). The peaks of low and high EPM contained two populations and the peak of medium EPM contained three populations all characterized by normal volume distributions of uniform coefficient of variation between 11% and 14%. The small cells in the peaks of high and medium EPM were normolblasts and the other cells were lymphocytes. The biological significance of these results is discussed.     

Target cells for Friend virus-induced erythroid bursts in vitro

Erythropoietin (Epo) acts on mouse bone marrow cells in vitro in plasma clot or methyl cellulose culture systems to induce the formation of single erythroid colonies, or clusters of erythroid colonies termed bursts. Our laboratory has recently reported the observation that infection of mouse bone marrow cells in vitro with the polycythemia-inducing strain of Friend virus (FV) resulted in the formation of erythroid bursts after 5 days in plasma clot culture in the absence of added Epo. We have now used this system to characterize the target cells for this FV-induced erythroid transformation. The greatest number of FV bursts were observed when marrow cells were obtained from mice whose erythropoiesis had been stimulated by bleeding or phenylhydrazine treatment. Bleeding also resulted in an increase in the number of FV bursts following the infection of spleen cells in vitro. Hypertransfusion of mice, which results in decreased erythropoiesis, yielded a reduced number of FV bursts in vitro, as did prior treatment with actinomycin D. Cell separation studies using velocity sedimentation at unit gravity showed that the cells, which give rise to FV bursts, sedimented with a modal sedimentation velocity between 5.1–8.5 mm/hr. The Epo-dependent colony-forming unit erythroid (CFU-E), which gives rise to a single erythroid colony, also sediments with a modal velocity between 5.1–8.5 mm/hr, while the Epo-dependent day 8 burst-forming unit erythroid (day 8 BFU-E) sediments with a modal velocity between 3.0–6.0 mm/hr. A 20 min incubation of marrow cells with high specific activity ³H-thymidine, prior to virus infection, resulted in a 75–80% reduction in the number of FV bursts. Mixing cells from the upper portion of the gradient, which yielded no FV bursts, with cells from an area in which high numbers of FV bursts were observed did not result in the inhibition of burst formation. These experiments indicate that the primary target cells for FV bursts in vitro are most probably erythroid precursor cells that have matured beyond the day 8 BFU-E and are closely related to the CFU-E.     

Subpopulations of chicken B lymphocytes.

Immunoglobulin-synthesizing cells from the spleen and bursa were fractionated by the 1 X G sedimentation velocity technique and characterized by their ability to synthesize immunoglobulin and by staining with fluorescent anti-light chain chain. Four subpopulations of immunoglobulin-synthesizing cells were identified. In the bursa, slowly sedimenting (S 2.3 mm/hr) and rapidly sedimenting (S greater than 3.5 mm/hr) subpopulations with surface immunoglobulin were present; in the spleen, a slowly sedimenting (S 2.3 mm/hr) subpopulation with surface immunoglobulin and plasma cells (S greater than 3.5 mm/hr) with large concentrations of intracellular immunoglobulin existed. The subpopulations differed most markedly in their ability to synthesize immunoglobulin (cpm Ig synthesized/10(6) Ig-positive cells); the rates of immunoglobulin synthesis were in the ratio 1:2:1:900. The slowly sedimenting B cells from the spleen and both subpopulations of B cells from the bursa released small amounts of immunoglobulin into the culture media, whereas, the plasma cells released immunoglobulin at a rate as much as 3700 times greater. Bursal B cells could be further distinguished from splenic B cells by a greater amount of DNA synthesis.     

Heterogeneity of in vitro colony- and cluster-forming cells in the mouse marrow: segregation by velocity sedimentation.

C57BL bone marrow cells were separated on the basis of their sedimentation velocity at unit gravity and cell fractions cultured in agar using three types of colony stimulating factor (CSF). Colony-forming cells separated as a single peak (s equal 4.4 mm/hr) in cultures stimulated by mouse lung conditioned medium (CSFMLCM) or endotoxin serum (CSFES). Cluster-forming cells were separable into two peaks and the majority were larger than colony-forming cells (s equal 5.7 mm/hr). Partial segregation of colony-forming cells was observed according to the morphological types of colonies generated, large cells tending to generate macrophage colonies and small cells, granulocytic colonies. Large colony-forming cells were more responsive to stimulation by CSF than small cells. Human urine (CSFHU) appeared unable to proliferation of most small colony-forming cells. Colony-forming cells appear to be a highly heterogeneous population with intrinsic differences in responsiveness to CSF and with differing capacities to generate colonies whose cells differentiate to granulocytes of macrophages.     

MODULATION OF IN VITRO ERYTHROPOIESIS: ENHANCEMENT OF ERYTHROID COLONY GROWTH BY CYCLIC NUCLEOTIDES

Mammalian erythropoiesis, as assayed by erythroid colony formation in vitro, is enhanced by cyclic adenosine nucleotides and agents which are capable of raising intracellular cyclic AMP (cAMP) levels. With canine marrow cells as target, this enhancement was shown to be specific for cAMP and its mono- and dibutyryl derivatives. Adenosine and its derivatives, such as AMP, ADP and ATP, and other cyclic nucleotides, such as cGMP, dibutyryl-cGMP, cCMP and cIMP and sodium butyrate were inactive. The phosphodiesterase inhibitor, RO-20-1724, and the adenyl cyclase stimulator, cholera enterotoxin, both markedly increased colony numbers. Studies with tritiated thymidine showed that about 50% of the cells responding to either erythropoietin (ESF) or dibutyryl cAMP (db-cAMP) were in DNA synthesis. However, by unit gravity sedimentation velocity analysis, the peak of ESF-responsive colony forming cells sedimented more rapidly (8.7 ± 0.2 mm/hr) than the peak of db-cAMP-responsive cells (7.5 ± 0 mm/hr). These results demonstrate that adenyl cyclase-linked mechanisms influence in vitro erythropoietic proliferation and suggest that other hormones and simple molecules might interact with surface receptors and thus modulate the action of ESF at the cellular level.     

Immunogenicity of allograft components: II. Relative immunogenicity of rat kidney parenchymal versus “passenger” cells

Well-perfused adult DA kidneys were enzymatically dispersed under conditions which do not affect the expression of cell surface major histocompatibility antigens. The kidney cell suspensions were separated via sedimentation at unit gravity into three fractions: I, rapidly sedimenting (>6.5 mm/hr) enriched for kidney tubular and glomerular cells and depleted of passenger leukocytes (76 and 8%, respectively); II, intermediate (5.1–6.0 mm/hr) mixed population equivalent to the unseparated kidney cell suspension (52% tubular and glomerular cells, 20% endothelial cells, and 28% passenger leukocytes); and III, slow sedimenting (<5.0 mm/hr) enriched for passenger leukocytes (63%). The three isolated fractions were analyzed for their ability to accelerate allograft rejection in the “primed heart rejection assay.” The cells in fraction I were unable to reduce heart allograft survival, while the cells from fraction III reduced it significantly. Cells from fraction II were intermediary effective. The results are in agreement with the hypothesis that the urine-producing apparatus of rat kidney is relatively nonimmunogenic, while the main stimulus for graft rejection is provided by the “passenger” cell component.     

Serum of lipopolysacharide-treated mice contains two types of colony-stimulating factor,separable by affinity chromatography

Serum from mice traated with bacterial lipopolysaccharide (LPS) was fractionated by Con A-Sepharose affinity chromatography, and assayed in vitro for colony-stimulating factor (CSF) using mouse bone marrow cells. The CSF failing to bind to concanavalin A-Sepharose (pool A) had similar biological properties to the unfractionated serum, i.e., it stimulated the formation of about equal numbers of granulocytic, mixed granulocyte-macrophage and macrophage colonies. The fraction eluted from the Con A-Sepharose column with α-methyl-D-glucopyranoside (pool B) had a steeper dose-response curve than either the unfractionated serum or the pool A CSF and most of the colonies were composed of macrophages. A mixture of the pool A and pool B CSFs stimulated colonies in a similar way as unfractionated serum and pool A. The apparent molecular weights of the two types of CSF were determined by two different gel-filtration procedures. Sephacryl S-200 gel-filtration suggested an apparent molecular weight of 85,000 for pool A CSF and 180,000 for pool B CSF. Gel-filtration on Sepharose CL-6B in the presence of guanidine hydrochloride (6M) yielded an apparent molecular weight of approximately 23,000 for pool A CSF and 33,000 for pool B CSF. The colony-forming cells (CFC) responding to pool B CSF were found to have a relatively high sedimentation velocity (peak sedimentation velocity 5.6–6.2 mm/hr) compared to the CFC responding to mouse-lung conditioned medium (MLCM) whose peak sedimentation velocity was between 4.0–4.5 mm/hour. The CFC responding to pool A CSF had an intermediate sedimentation velocity (peak 4.6–5.2 mm/hour). A time-course analysis of the morphology of clones or colonies in cultures stimulated with either MLCM or pool B CSF showed that the proporation of different colony types depends significantly on the incubation period and suggested that pool B CSF induced an early commitment of CFC towards macrophage differentiation.     

Reverse banding of Japanese quail microchromosomes.

Cells isolated from adult and fetal rat liver and ascites hepatoma were separated into distinct populations by velocity sedimentation at unit gravity. Normal adult liver ceils sediment with modal velocities ranging from 5 to 50 mm/h. Volume analysis using a Coulter-type counter demonstrated that the separation was based primarily on cell size. Appreciable differences were observed in the sedimentation velocity distribution of cells isolated from different normal lobes or regenerating liver. Most fetal rat liver cells sediment with velocities inferior to 12 mm/h. Ascites (Novikoff) hepatoma cells present a velocity distribution more similar to that of fetal than to normal adult liver cells. The results are discussed in terms of cell-size changes associated with liver maturation, regeneration or transformation.     

Direct comparison of the rapid axonal transport of norepinephrine and dopamine-β-hydroxylase activity

Stop-flow techniques were used to examine the rapid axonal transport of norepinephrine in rabbit sciatic nerves. When the midpoint of a nerve incubated in vitro was cooled to 2°C while the remainder was kept at 37°C, norepinephrine accumulated proximal to the cooled region at a rate corresponding to an average transport velocity between 5 and 6 mm/hr in a distal direction. Since only about half of the norepinephrine appeared to be free to move, the mean velocity of the moving fraction was probably twice as great. No norepinephrine accumulated distal to a broad cooled region under conditions in which there would have been a significant accumulation of dopamine-β-hydroxylase activity. Therefore, unlike dopamine-β-hydroxylase, norepinephrine may not be subject to rapid retrograde transport. When nerves that had been locally cooled for 1.5 hr were rewarmed uniformly to 37°C, a wave of norepinephrine moved exclusively in a distal direction. The peak of this wave moved at a velocity of 12.2 ± 0.5 mm/hr or 293 ± 12 mm/day; the front of the wave moved at about 18 mm/hr. or 430 mm/day; and the tail probably moved faster than 6 mm/hr. This spectrum of velocities was virtually identical to the one displayed by the wave of dopamine-β-hydroxylase activity that was generated under the same conditions. Our results are consistent with the conclusion that all axonal structures containing norepinephrine also contain dopamine-β-hydroxylase, but they are not consistent with the converse.     

Role of accessory cells in the in vitro growth of aggregate-derived murine T-cell colonies

C3H/HeJ lymph node cells (LNC) were seeded in 35-mm petri dishes containing 0.8% methylcellulose, 10% fetal calf serum, 2-mercapthoethanol, and supernatant from PHA or Con A-stimulated spleen cells. After 3–4 days incubation at 37 °C, colonies containing >50 cells appeared. The cells from individual colonies stained with a fluorescent anti-Thy-1 antiserum, and colony formation was prevented by treating the LNC with radiation or anti-T-cell serum + complement before culturing. When fewer than 1?2 × 10⁶ LNC were seeded, the number of colonies formed decreased exponentially; this observation suggested colony formation might require cell-cell interaction. Formation of cellular aggregates could be seen as early as 4–20 hr after plating. Colony formation of 2?5 × 10⁵ LNC was promoted by adding irradiated or anti-T serum + complement-treated LNC, and colony formation was inhibited by carbonyl iron treatment to remove adherent cells. Cell separation by velocity sedimentation showed colony promoting activity was associated with cells sedimenting at 4 mm/hr and also >6 mm/hr. These are properties similar to those of accessory cells that are required for immune responses in vitro and in vivo. Colony formation was also increased in LNC from tumor allograft immune mice, and in the uterine lymph nodes from mice bearing an allogeneic fetus. T-Cell colonies produced by direct plating of LNC in this system arise from proliferation of cellular aggregates, and are primarily a measure of accessory cell activity.     

Antigen-inhibited B-lymphocyte differentiation. X. Sedimentation velocity characterization of antigen-binding cells and antibody-forming-cell progenitors in the in vitro microculture immune response of unprimed CBA mice to NIP--POL antigen.

The B lymphocytes serving as antibody-forming-cell (AFC) progenitors have been investigated using two different types of separation methods. Sedimentation velocity fractionation was used to separate subsets of B lymphocytes differing primarily in size. Fractionation on a 4-hydroxy-3-iodo-5-nitrophenylacetic acid (NIP)-gelatin matrix was used to separate NIP-binding cells, a population highly enriched for cells with surface Ig receptors specific for the NIP hapten. Assessment of the functional capacity of the separated B cells was by culture at limiting dilution in the presence of thymus “filler” cells, using the T-independent antigen NIP-POL (polymerized bacterial flagellin) to induce antibody formation. Splenic AFC-progenitors from both adult conventional and neonatal germ-free mice were a physically heterogeneous population, with activity in small, medium, and large lymphocytes. The cells enriched by NIP-gelatin binding, whether isolated and counted directly or isolated and assayed as AFC-progenitors, were no less heterogeneous. These NIP-binding cells resembled in sedimentation characteristics the overall B-cell and overall NIP-specific AFC-progenitor populations, except for some relative enrichment of medium-sized cells (S value, 5.5 mm/hr). The small (S value, 3.4 mm/hr) B-cell region of adult mouse spleen contained both NIP-binding cells and cells responsive as AFC-progenitors in the microculture assay. This contrasts with the results of the in vivo adoptive immune assay, where the smaller B-cell region is unresponsive in unprimed adult animals.     

Early precursors in the erythroid lineage are the specific target cells of avian erythroblastosis virus in vitro

In chickens the erythroid differentiation proceeds from stem cells to erythrocytes through several intermediate steps which have been identified in vivo and in vitro. To determine whether Avian erythroblastosis virus (AEV) is able to transform in vitro either one or several types of these precursors, bone marrow cells were separated by physical and immunological methods. It was found that the target cells which could be transformed in vitro by AEV were cells of light density (1.060-1.065 g/cm3), having a modal sedimentation velocity at unit gravity between 4.0 and 6.0 mm/hr, expressing an immature antigen at a low level and a brain-related antigen at a high level. These results indicated that the target cells of neoplastic transformation by AEV were early erythroid precursors, since these precursors shared the same physical and immunological properties with AEV target cells.     

Effect of electric field on erythrocyte sedimentation rate. II. Dependence on electric current

We measured the electric current dependence of sedimentation curves of swine erythrocytes in a saline solution at the volume fraction of erythrocytes H = 0.091 and 0.220. The sedimentation curve fitted well to the exponential type equation l = a[1-exp(-bt)] at the upward initial electric current I0 = 0.50 mA, 1.01 mA and 1.50 mA, where l is the length of the medium layer at time t, and a and b are phenomenological parameters. The initial slope v0 of sedimentation curve was enhanced from 0.68 mm/hr at I0 = 0 mA to 2.85 mm/hr, 3.87 mm/hr and 5.50 mm/hr at I0 = 0.50 mA, 1.01 mA and 1.50 mA, respectively, for H = 0.220. We also made sedimentation measurements of erythrocytes in their own plasma at H = 0.220 and 0.316. Sedimentation curves coincided with the sigmoidal type equation l = l infinity/[1 + (t50/t)beta] at I0 = 0 mA and 0.50 mA, where l infinity is l at t----infinity, t50 is the time when the plasma level falls to l infinity/2 and beta is a constant. The maximum slope vmax of sedimentation curve increased from 13.29 mm/hr at I0 = 0 mA to 18.65 mm/hr at I0 = 0.50 mA for H = 0.220.     

Role of Corynebacterium parvum in the activation of peritoneal macrophages. II. Identification of distinguishable anti-tumor activities by macrophage subpopulations

Two different mechanisms of murine macrophage (MP) antitumor activity are described in this report. C. parvum-activated peritoneal MPs were tested for cytotoxic and cytostatic activity 4 days after ip immunization. Cytotoxic activity could be distinguished from cytostatic activity using two different assay protocols. When MPs were separated by 1g velocity sedimentation, cytotoxic MPs were confined to high velocity fractions. In contrast, cytostatic MPs were found in cell fractions with velocities as low as 5.2 mm/hr. These two MP activities were also distinguishable by culturing at 37 degrees C for 24 hr. Cytotoxicity was abrogated when MPs were incubated in MEM, or MEM supplemented with lymphokine (LK) or indomethacin. In contrast, cytostasis remained at high levels when the cells were incubated with LK or indomethacin. Cytotoxicity was not retained after overnight culture even if LPS was present, or if various spleen or non-adherent peritoneal exudate cells were cocultured with the cytotoxic effector cells. Assays done to determine the presence of suppressor cells failed to find any inhibitory cell type. The phagocytic index, acid phosphatase activity, and H2O2 secretion were also measured before and after overnight culture. Acid phosphatase and phagocytic activities did not decline whereas H2O2 secretion declined significantly. These data indicate that in response to C. parvum, at least two different effector cell types with distinct antitumor activities are generated. Cytotoxicity, like the ability of cells to secrete H2O2, is found to be a short-lived function of CP stimulated MPs. In contrast, cytostasis is a function retained longer by MPs in culture.     

Cell-cycle differences of HL-60 leukemia cells fractionated by centrifugal elutriation

HL-60 leukemia cells were fractionated into G1 and S/G2 populations using a rapid centrifugal elutriation technique, and studied for differences between the cell-cycle phases. The G1 fraction was found to contain smaller cells with a sedimentation velocity of 7 mm/h. The S/G2 fraction consisted of larger cells with a sedimentation velocity of 125 mm/h. The latter fraction was found to have a peak level of the enzyme (2'-5')An-binding protein, as compared to the G1 fraction, indicating a possible role for (2'-5')An-binding protein and its products in the growth regulation of these leukemic cells. In addition, cytofluorometric analysis of fractionated HL-60 cells indicates that elutriation is an effective fractionation method, rapidly yielding large numbers of cells for study, without the use of chemical treatments.